Removal of Radionuclides by Metal-organic Framework-based Materials

Xiang-Xue WANG; Shu-Jun YU; Xiang-Ke WANG; [in Chinese]; [in Chinese]; [in Chinese]

doi:10.15541/jim20180211

[1] Y LAN W, Y LIU, J AI Y et al. The effect of pH on the U(VI) sorption on graphene oxide (GO): a theoretical study. Chemical Engineering Journal, 343, 460-466(2018).

[2] W YAO, X WANG X, W PANG H et al. Removal of radionuclides by metal oxide materials and mechanism research. Scientia Sinica Chimica, 48, 58-73(2018).

[3] X WANG X, S CHEN Z, Y YANG S et al. Synthesis of Fe₃O₄-based nanomaterials and their application in the removal of radionuclides and heavy metal ions. Progress in Chemistry, 30, 225-242(2018).

[4] J YU S, X WANG X, W PANG H et al. Boron nitride-based materials for the removal of pollutants from aqueous solutions: a review. Chemical Engineering Journal, 333, 343-360(2018).

[5] X WANG X, J YU S, T YANG S et al. Interaction of radionuclides with natural and manmade materials using XAFS technique. Science China Chemistry, 60, 170-187(2016).

[6] L ZHANG C, X LI, Y LIU et al. Porous Fe₂O₃ microcubes derived from metal organic frameworks for efficient elimination of organic pollutants and heavy metal ions. Chemical Engineering Journal, 336, 241-252(2018).

[7] C GU P, W YAO, Y LIANG et al. Adsorption of radionuclide uranium onto carbon-based nanomaterials from aqueous systems. Process in Chemistry, 29, 1062-1071(2017).

[8] C DU Y, Q HOU R, K WANG X et al. In-situ growth of Nb₂O₅ nanorods on diatomite and highly effective removal of Cr(VI). Journal of Inorganic Materials, 33, 557-564(2018).

[9] B ZHANG Z, J CHEN H, Y HUANG S et al. Synthesis of functional nanoscale zero-valent iron composites for the application of radioactive uranium enrichment from environment: a review. Acta Chimica Sinica, 75, 560-574(2017).

[10] Y DU, J WANG, Q WANG H et al. Research on sorption mechanism of radionuclides by manufactured nanomaterials. Journal of. Agro-Environment Science, 35, 1837-1847(2016).

[11] Y MA F, N WANG X, H MENG et al. Influence of preparation method on oxidation degree of graphene oxide and adsorption for Th(IV) and U(VI). Journal of Inorganic Materials, 31, 454-460(2016).

[12] L XING J, C GU P, T WEN et al. Experimental and theoretical calculation investigation on efficient Pb(II) adsorption on etched Ti₃AlC₂ nanofibers and nanosheets. Environmental Science: Nano, 5, 946-955(2018).

[13] W PANG H, W YAO, H WU Y et al. In-situ reduction synthesis of manganese dioxide@polypyrrole core/shell nanomaterial for highly efficient enrichment of U(VI) and Eu(III). Science China Chemistry, 2018, 1-12.

[14] L YIN, X WANG X, S SONG et al. Interaction of U(VI) with ternary layered double hydroxides by combined batch experiments and spectroscopy study. Chemical Engineering Journal, 338, 579-590(2018).

[15] X WANG X, L YIN, Y WANG P et al. L-cysteine intercalated layered double hydroxide for highly efficient capture of U(VI) from aqueous solutions. Journal of Environmental Management, 217, 468-477(2018).

[16] L BAI Z, X DAI, W LIU et al. Highly sensitive and selective uranium detection in natural water systems using a luminescent mesoporous metal-organic framework equipped with abundant lewis basic sites: a combined batch, X-ray absorption spectroscopy, and first principles simulation investigation. Environmental Science & Technology, 51, 3911-3921(2017).

[17] X WANG X, J LI, X ZHAO G et al. Metal-organic framework- based materials: superior adsorbents for the capture of toxic and radioactive metal ions. Chemical Society Reviews, 47, 2322-2356(2018).

[18] W YAO, W PANG H, H WU Y et al. Synthesis of rod-like metal-organic framework (MOF-5) nanomaterial for efficient removal of U(VI): batch experiments and spectroscopy study. Science Bulletin, 63, 831-839(2018).

[19] J HOWARTH A, J DROUT R, K OTAKE et al. Efficient capture of perrhenate and pertechnetate by a mesoporous Zr metal-organic framework and examination of anion binding motifs. Chemistry of Materials, 30, 1277-1284(2018).

[20] L WANG Y, Y LIU Z, X LI Y et al. Umbellate distortions of the uranyl coordination environment result in a stable and porous polycatenated framework that can effectively remove cesium from aqueous solutions. Journal of America Chemistry Society, 137, 6144-6147(2015).

[21] J SCHWEIGER M, D BANERJEE, D KIM et al. Removal of TcO₄- ions from solution: materials and future outlook. Chemical Society Reviews, 45, 2724-2739(2016).

[22] Y HUANG S, H WU Y, W PANG H et al. Efficient elimination of U(VI) by polyethyleneimine decorated fly ash. Inorganic Chemistry Frontiers, 5, 2399-2407(2018).

[23] X WANG X, J YU S, L TAN X et al. Sorption of radionuclides from aqueous systems onto graphene oxide-based materials: a review. Inorganic Chemistry Frontiers, 2, 593-612(2015).

[24] Y ZHANG, M WANG L, F DUAN L et al. Synthesis and characterization of MnFe₂O₄ with different morphologies and their application in water treatment. Journal of Inorganic Materials, 29, 763-768(2014).

[25] B LIU S, W ABNEY C, M CARBONI et al. Highly porous and stable metal-organic frameworks for uranium extraction. Chemical Science, 4, 2396-2402(2013).

[26] Q BAI Z, Y YUAN L, L ZHU et al. Introduction of amino groups into acid-resistant MOFs for enhanced U(VI) sorption. Journal of Materials Chemistry A, 3, 525-534(2015).

[27] W MA, S SHEN S, N LI L et al. A combined experimental and theoretical study on the extraction of uranium by amino-derived metal-organic frameworks through post-synthetic strategy. ACS Applied Materials & Interfaces, 8, 31032-31041(2016).

[28] P SHENG D, L ZHU, C XU et al. Identifying the recognition site for selective trapping of ⁹⁹TcO₄- in a hydrolytically stable and radiation resistant cationic metal-organic framework. Journal of America Chemistry Society, 139, 14873-14876(2017).

[29] L ZHU, C XU, P SHENG D et al. Efficient and selective uptake of TcO₄- by a cationic metal-organic framework material with open Ag+ sites. Environmental Science & Technology, 51, 3471-3479(2017).

[30] P YANG P, Q LIU, Y LIU J et al. Interfacial growth of a metal-organic framework (UiO-66) on functionalized graphene oxide (GO) as a suitable seawater adsorbent for extraction of uranium(VI). Journal of Materials Chemistry A, 5, 17933-17942(2017).

[31] L GUO W, Y YUAN L, N ZHANG et al. Extending the use of highly porous and functionalized MOFs to Th(IV) capture. ACS Applied Materials & Interfaces, 9, 25216-25224(2017).

[32] L HUANG H, H LIU D, G PENG Y et al. Radioactive barium ion trap based on metal-organic framework for efficient and irreversible removal of barium from nuclear wastewater. ACS Applied Materials & Interfaces, 8, 8527-8535(2016).

[33] J LIU, Y YUAN G, Y TIAN et al. Schiff base anchored on metal-organic framework for Co(II) removal from aqueous solution. Chemical Engineering Journal, 326, 691-699(2017).

[34] J GAO Y, L FENG M, B ZHANG et al. An easily synthesized microporous framework material for the selective capture of radioactive Cs+ and Sr²+ ions. Journal of Materials Chemistry A, 6, 3967-3976(2018).

[35] Y LIANG, X WANG X, W YAO et al. Synthesis of novel flower-like layered double oxides/carbon dots nanocomposites for U(VI) and ²⁴¹Am(III) efficient removal: batch and EXAFS studies. Chemical Engineering Journal, 332, 775-786(2018).

[36] X WANG X, H WU Y, J YU S et al. The synergistic elimination of uranium(VI) species from aqueous solution using bi-functional nanocomposite of carbon sphere and layered double hydroxide. Chemical Engineering Journal, 342, 321-330(2018).

[37] W PANG H, X WANG X, Y LIU et al. Effect of graphene oxide surface modification on the elimination of Co(II) from aqueous solutions. Chemical Engineering Journal, 344, 380-390(2018).

[38] J YU S, S SONG, J WANG et al. One-pot synthesis of graphene oxide and Ni-Al layered double hydroxides nanocomposites for the efficient removal of U(VI) from wastewater. Science China Chemistry, 60, 415-422(2017).

[39] S CHEN Z, J YU S, X WANG X et al. Interaction mechanism of radionickel on Na-montmorillonite: influences of pH, electrolyte cations, humic acid and temperature. Chemical Engineering Journal, 302, 77-85(2016).

[40] S SONG, L YIN, X WANG X et al. Rationally designed core-shell and yolk-shell magnetic titanate nanosheets for efficient U(VI) adsorption performance. Environmental Pollution, 238, 725-738(2018).

[41] X LI, S ZHANG, C GU P et al. Recent advances in layered double hydroxide-based nanomaterials for the removal of radionuclides from aqueous solution. Environmental Pollution, 240, 493-505(2018).

[42] S CHEN Z, C SONG W, X WANG X et al. Enhanced immobilization of U(VI) on Mucor circinelloides in presence of As(V): batch and XAFS investigation. Environmental Pollution, 237, 228-236(2018).

[43] M FANG, Q TAN L, L TAN X et al. Core-shell hierarchical C@Na₂Ti₃O₇·9H₂O nanostructures for the efficient removal of radionuclides. Environmental Science: Nano, 5, 1140-1149(2018).

[44] H FAGHIHIAN, S NAEIMI. Performance of novel adsorbent prepared by magnetic metal-organic framework MOF modified by potassium nickel hexacyanoferrate for removal of Cs+ from aqueous solution. Separation and Purification Technology, 175, 255-265(2017).

[45] Y LIU, L ZHANG C, X LI et al. Highly uranium elimination by crab shells-derived porous graphitic carbon nitride: batch, EXAFS and theoretical calculations. Chemical Engineering Journal, 346, 406-415(2018).

[46] D ZOU Y, X WANG X, Z HU Y et al. Superior sorption capacities of Ca-Ti and Ca-Al bimetallic oxides for U(VI) from aqueous solutions. Chemical Engineering Journal, 316, 419-428(2017).

[47] J WANG, S CHEN Z, X PU Z et al. Synthesis of magnetic Fe₃O₄/CFA composites for the efficient removal of U(VI) from wastewater. Chemical Engineering Journal, 320, 448-457(2017).

[48] L ZHANG C, S CHEN Z, X LI et al. Synthesis of ordered mesoporous carbonaceous materials and its highly efficient capture of uranium from solutions. Science China Chemistry, 61, 281-293(2018).

[49] B SUN Y, X WANG X, H LU S et al. Plasma-facilitated synthesis of amidoxime/carbon nanofiber hybrids for effective enrichment of ²³⁸U(VI) and ²⁴¹Am(III). Environmental Science & Technology, 51, 12274-12282(2017).

[50] X WANG X, J WANG, X ZHAO G et al. Polyvinylpyrrolidone and polyacrylamide intercalated molybdenum disulfide as adsorbents for enhanced removal of chromium(VI) from aqueous solutions. Chemical Engineering Journal, 334, 569-578(2018).

[51] X YANG D, G SONG, X WANG X et al. One-pot synthesis of arginine modified hydroxyapatite carbon microsphere composites for efficient removal of U(VI) from aqueous solutions. Science Bulletin, 62, 1609-1618(2017).

[52] R ZHANG, S SONG, Y HUANG S et al. Simultaneous removal of U(VI) and humic acid on defective TiO_2-x investigated by batch and spectroscopy techniques. Chemical Engineering Journal, 325, 576-587(2017).

[53] Y MEI H, L TAN X, Q TAN L et al. Coagulation behavior of humic acid in aqueous solutions containing Cs+, Sr²+ and Eu³+: DLS, EEM and MD simulation. Environmental Pollution, 235, 835-843(2018).

[54] J ZHANG L, Y ZHANG J, N ZHANG et al. Adsorption of uranyl ions on amine-functionalization of MIL-101(Cr) nanoparticles by a facile coordination-based post-synthetic strategy and X-ray absorption spectroscopy studies. Scientific Reports(2015).

[55] Z PAN Z, E GIAMMAR D, H WEN et al. Enhanced uranium immobilization by phosphate amendment under variable geochemical and flow conditions: insights from reactive transport modeling. Environmental Science & Technology, 52, 5841-5850(2018).

[56] L WANG, J ZHANG Y, H LAN J et al. Adsorption of uranyl species on hydroxylated titanium carbide nanosheet: a first-principles study. Journal of Hazardous Materials, 308, 402-410(2016).

[57] K CHEN, Y YUAN L, L WANG et al. Loading actinides in multilayered structures for nuclear waste treatment: the first case study of uranium capture with vanadium carbide MXene. ACS Applied Materials & Interfaces, 8, 16396-16403(2016).

[58] X GUI D, X YANG Z, T ZHENG et al. Overcoming the crystallization and designability issues in the ultrastable zirconium phosphonate framework system. Nature Communications, 8, 15369(2017).

[59] D SHAO D, , D SHENG G. Effect of pH and ionic strength on sorption of Eu(III) to MX-80 bentonite: batch and XAFS study. Radiochimica Acta, 97, 621-630(2009).

[60] L CHEN C, L TAN X, M REN X et al. Analytical approaches to the speciation of lanthanides at solid-water interfaces. TrAC Trends in Analytical Chemistry, 61, 107-132(2014).

[61] F LUO, L CHEN J, L DANG L et al. High-performance Hg²+ removal from ultra-low-concentration aqueous solution using both acylamide-and hydroxyl-functionalized metal-organic framework. Journal of Materials Chemistry A, 3, 9616-9620(2015).

[62] Q XU W, M NIE Z, D BANERJEE et al. Zirconium-based metal-organic framework for removal of perrhenate from water. Inorganic Chemistry, 55, 8241-8243(2016).

[63] F HOSKINS B, R ROBSON. Infinite polymeric frameworks consisting of three dimensionally linked rod-like segments. Journal of the American Chemical Society, 111, 5962-5964(1989).

[64] A NALAPARAJU, W JIANG J. Ion exchange in metal-organic framework for water purification: insight from molecular simulation. The Journal of Physical Chemistry C, 116, 6925-6931(2012).